Multi-functional sensing methods and apparatus therefor

1. An apparatus for detecting the distance between a nozzle assembly for a machining process and a workpiece to be machined, comprising: a shield means for surrounding a nozzle assembly, said shield means being open at one end to permit a piercing force from said nozzle assembly to exit said shield means; a means for supplying a gas to create a pressure within said shield means; and a sensing means for detecting an increase in pressure caused within said shield means as said open end of said shield means approaches a workpiece to be machined, said sensing means being disposed between and in fluid communication with said means for supplying gas and said shield means.

2. A An apparatus for detecting the distance between a nozzle assembly for a machining process and a workpiece to be machined according to claim 1, further comprising a controlling means which monitors said sensing means and detects when said pressure within said shield means reaches a pressure which corresponds to a predetermined gap distance between nozzle assembly and said workpiece for a machining process.

3. An apparatus for detecting the distance between a nozzle assembly for a machining process and a workpiece to be machined according to claim 2, wherein said controlling means also monitors the position of said nozzle assembly upon establishing said gap distance and compares this position with a predetermined reference position to determine a thickness of said workpiece.

4. An apparatus for detecting the distance between a nozzle assembly for a machining process and a workpiece to be machined according to claim 1, further comprising a controlling means which monitors said sensing means and detects when said pressure within said shield means varies outside of a pressure range, said range corresponding to an acceptable predetermined range of gap distances between nozzle assembly and said workpiece for a machining process.

5. An apparatus for detecting the distance between a nozzle assembly for a machining process and a workpiece to be machined according to claim 1, wherein said piercing force is a concentrated beam energy selected from the group consisting of an abrasive waterjet, a pure waterjet, a laser, a plasma arc, a flame, and an electron beam.

6. An apparatus for detecting the distance between a nozzle assembly for a machining process and a workpiece to be machined according to claim 1, wherein said piercing force performs a machining operation selected from the group consisting of a cutting, a piercing, a drilling, a milling, and a turning operation, and combinations thereof.

7. A method of detecting the distance between a nozzle assembly for a machining process and a workpiece to be machined, comprising: supplying a gas to create a pressure within a shield means surrounding a nozzle assembly, said shield means being open at one end to permit a piercing force from said nozzle assembly to exit said shield means; detecting an increase in pressure caused within said shield means as said open end of said shield means approaches a workpiece to be machined; monitoring said increase in pressure within said shield means; and detecting when said pressure reaches a pressure which corresponds to a predetermined gap distance between said nozzle assembly and said workpiece for a machining process.

8. A method of detecting the distance between a nozzle assembly for a machining process and a workpiece to be machined according to claim 7, wherein said monitoring step further comprises monitoring a position of said nozzle assembly upon establishing said gap distance, and comparing this position with a predetermined reference position to determine a thickness of said workpiece.

9. A method of detecting the distance between a nozzle assembly for a machining process and a workpiece to be machined according to claim 7, further comprising the steps of monitoring said sensing means and detecting when said pressure within said shield means varies outside of a pressure range, said range corresponding to an acceptable predetermined range of gap distances between nozzle assembly and said workpiece for a machining process.

10. A method of detecting the distance between a nozzle assembly for a machining process and a workpiece to be machined according to claim 7, wherein said piercing force is a concentrated beam energy selected from the group consisting of an abrasive waterjet, a pure waterjet, a laser, a plasma arc, a flame, and an electron beam.

11. A method of detecting the distance between a nozzle assembly for a machining process and a workpiece to be machined according to claim 7, wherein said piercing force performs a machining operation selected from the group consisting of a cutting, a piercing, a drilling, a milling, and a turning operation, and combinations thereof.

12. An apparatus for sensing a pierce-through condition of a material made by a piercing force, comprising: a shield means for surrounding a source of a piercing force; a means for supplying a gas to create a pressure within said shield means; and a sensing means for detecting a decrease in pressure caused within said shield means by said pierce-through condition created by said piercing force, said sensing means being disposed between and in fluid communication with said means for supplying gas and said shield means.

13. An apparatus for sensing a pierce-through condition of a material according to claim 12, wherein said piercing force is a concentrated beam energy selected from the group consisting of an abrasive waterjet, a pure waterjet, a laser, a plasma arc, a flame, and an electron beam.

14. An apparatus for sensing a pierce-through condition of a material according to claim 12, wherein said piercing force performs a machining operation selected from the group consisting of a cutting, a piercing, a drilling, a milling, and a turning operation, and combinations thereof.